Energy absorbing steering apparatus

ABSTRACT

An energy absorbing steering apparatus for a vehicle includes a support member for supporting a steering column by detachably attaching the steering column to a vehicle body and an energy absorption apparatus for relatively movably supporting the steering column relative to the vehicle body in a frontward direction of the vehicle body. The energy absorbing steering apparatus is designed for absorbing impact energy applied to the steering column. The energy absorption apparatus includes a support pin supported by the steering column, a first absorption member provided along the support pin and having a connection portion provided at one end of the first absorption member and connected to the vehicle body for applying load to the support pin when the support pin moves relative to the support member, a second absorption member provided along the support pin and having a connection portion provided at one end of the second absorption member and connected to the vehicle body for applying load to the support pin when the support pin moves relative to the support member, a connection member connected to the connection portion of the first absorption member and the connection portion of the second absorption member for connecting the first absorption member and the second absorption member to the vehicle body, and a control apparatus for controlling the connection member to change the number of absorption members connected to the vehicle body corresponding to a drive condition.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is based on and claims priority under 35 U.S.C. § 119to Japanese Patent Application 2004-190401, filed on Jun. 28, 2004, theentire content of which is incorporated herein by reference.

FIELD OF THE INVENTION

This invention generally relates to an energy absorbing steeringapparatus.

BACKGROUND

When a vehicle collides with another vehicle or a building, a driver ofthe vehicle collides with a steering apparatus by inertia force.Conventional energy absorbing steering apparatus includes an energyabsorbing apparatus for absorbing the impact energy.

In the energy absorbing steering apparatus of this kind, the steeringcolumn is movably supported relative to a vehicle body so that thesteering column can move frontward relative to the vehicle when thedriver of the vehicle collides with the steering apparatus. The energyabsorbing steering apparatus further includes a member for absorbing theimpact energy applied from the driver.

However, load applied to the steering column from the driver can bevaried from different drive conditions. The load can be varied, forexample, when the vehicle is driven by various drivers, because weightsof the drivers are varied. Therefore, there is a danger that the energyabsorption steering apparatus cannot sufficiently absorb the impactenergy applied from the driver to the steering column. For overcomingthe problem described above, JP2002-362381A suggests an energy absorbingapparatus in which the amount of impact energy absorbed can becontrolled depending on the drive condition. In the energy absorbingsteering apparatus, the amount of impact energy absorbed can becontrolled by changing a rotational angle of a support pin therebychanging degree of deformation of an energy absorption plate deformed bythe support pin.

However, in the steering apparatus described in the document, therotational angle of the support pin is controlled by a motor. The motorneed to have high torque so that the support pin can be removed from theenergy absorption plate against counter force. Therefore, the motortends to become larger size and cause high manufacturing cost. Further,another mechanism for regulating the rotational angle of the support pinis required. As a result, the steering apparatus tends to be stilllarger size.

A need thus exists for an energy absorbing steering apparatus, in whichimpact energy can be preferably absorbed under various drive conditions,of simple configuration. The present invention has been made in view ofthe above circumstances and provides such an energy absorbing steeringapparatus for a vehicle.

SUMMARY OF THE INVENTION

According to an aspect of the present invention, an energy absorbingsteering apparatus for a vehicle includes a support member forsupporting a steering column by detachably attaching the steering columnto a vehicle body and an energy absorption apparatus for relativelymovably supporting the steering column relative to the vehicle body in afrontward direction of the vehicle body. The energy absorbing steeringapparatus is designed for absorbing impact energy applied to thesteering column. The energy absorption apparatus includes a support pinsupported by the steering column, a first absorption member providedalong the support pin and having a connection portion provided at oneend of the first absorption member and connected to the vehicle body forapplying load to the support pin when the support pin moves relative tothe support member, a second absorption member provided along thesupport pin and having a connection portion provided at one end of thesecond absorption member and connected to the vehicle body for applyingload to the support pin when the support pin moves relative to thesupport member, a connection member connected to the connection portionof the first absorption member and the connection portion of the secondabsorption member for connecting the first absorption member and thesecond absorption member to the vehicle body, and a control apparatusfor controlling the connection member to change the number of absorptionmembers connected to the vehicle body corresponding to a drivecondition.

BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing and additional features and characteristics of the presentinvention will become more apparent from the following detaileddescription considered with reference to the accompanying drawings,wherein:

FIG. 1 represents a schematic side view illustrating an energy absorbingsteering apparatus according to embodiments of the present invention;

FIG. 2 represents a side view illustrating the steering apparatusaccording to the embodiments of the present invention;

FIG. 3 represents a plane view illustrating the steering apparatus;

FIG. 4A represents a diagram for explaining an energy absorptionapparatus;

FIG. 4B represents a diagram for explaining the energy absorptionapparatus;

FIG. 5 represents a cross-sectional view illustrating the energyabsorption apparatus;

FIG. 6 represents a cross-sectional view illustrating a control pin;

FIG. 7 represents a diagram for explaining an action of a steeringapparatus according to a first embodiment of the present invention;

FIG. 8 represents a diagram for explaining an action of the steeringapparatus according to the first embodiment of the present invention;

FIG. 9 represents a diagram for explaining an action of the steeringapparatus according to the first embodiment of the present invention;

FIG. 10 represents a diagram for explaining an action of the steeringapparatus according to the first embodiment of the present invention;

FIG. 11 represents a diagram for explaining an action of a steeringapparatus according to a second embodiment of the present invention;

FIG. 12 represents a diagram for explaining an action of a steeringapparatus according to a third embodiment of the present invention;

FIG. 13 represents a diagram for explaining another example of an energyabsorption apparatus; and

FIG. 14 represents a diagram for explaining another example of an energyabsorption apparatus.

DETAILED DESCRIPTION

A first embodiment of the present invention will be explained withreference to drawing figures.

FIG. 1 represents a schematic side view illustrating an energy absorbingsteering apparatus (referred to as a steering apparatus in later part)according to the embodiment of the present invention. As illustrated inFIG. 1, the steering apparatus 1 includes a steering column apparatus 2(steering column) and a steering shaft 3 inserted into the steeringcolumn apparatus 2.

The steering column apparatus 2 is accommodated in a column cover K. Thesteering shaft 3 is rotatably supported by the steering column apparatus2 through bearings 4 and 5. A steering link (not illustrated) isconnected to the front end of the steering shaft 3. A steering wheel SWis attached to the rear end of the steering shaft 3. Here, and also inlater part of this document, “front” and “rear” are determined relativeto a vehicle.

Further, a column housing 2 a is provided at approximately middleportion of the steering column apparatus 2. A first support member 6 issecured to the column housing 2 a as a unit with the column housing 2.The first support member 6 is connected to a vehicle body 8 through abolt G1 so that the steering column 2 is supported by the vehicle body8. In addition, a second support member 7 (support member, illustratedin later figures) is secured to the rear side of the column housing 2 a.The second support member 7 is fixed to the vehicle body 8 through abolt G2 (connection bolt). Accordingly, the steering column apparatus 2is supported by the vehicle body 8 through the second support member 7.

The first support member 6 is configured so as to be detached from thevehicle body 8 when a predetermined load is applied to the steeringshaft 3 in a frontward longitudinal direction. In addition, the secondsupport member 7 is configured so as to be detached from the columnhousing 2 a when a predetermined load is applied to the steering shaft 3in a frontward longitudinal direction. As a result, the steering columnapparatus 2 is moved frontward when a predetermined load is applied tothe steering shaft 3 in a frontward longitudinal direction.

In addition, the column housing 2 a includes an energy absorptionapparatus 9. The energy absorption apparatus 9 has a function ofabsorbing impact energy applied to a driver from the steering wheel SWwhen the steering column apparatus 2 is detached from the vehicle body 8and moved frontward.

The steering apparatus 1 includes a sensor R as a detection apparatusaccommodated in a driver seat S for detecting a weight of a driver H. Adetection signal DG emitted by the sensor R is transmitted to acontroller 10 provided in the vehicle body 8 through an electric wire(not illustrated).

The controller 10 includes a memory 10 a, a central processing unit(CPU) 10 b, and an input/output circuit 10 c. The memory 10 a stores apredetermined standard weight. The controller 10 feeds the detectionsignal DG through the input/output circuit 10 c.

The CPU 10 b detects a weight of a driver H through the detection signalDG, and judges whether the weight of the driver H is equal to or morethan the standard weight or not. The CPU 10 b emits a drive current SGto the steering column apparatus 2 through the input/output circuit 10 ccorresponding to a judge result. In the embodiment, the CPU 10 b emitsthe drive current SG when the weight of the driver H is less than thestandard weight, and not emit the drive current SG when the weight ofthe driver H is equal to or more than the standard weight. Specifically,for example in the embodiment, the CPU 10 b emits the drive current SGto the steering column apparatus 2 when the CPU 10 b determines that theweight of the driver H is less than 80 kg, and not emit the drivecurrent SG when the CPU 10 b determines that the weight of the driver His equal to or more than 80 kg.

Further, the steering apparatus 1 includes a tilt mechanism C1. An angleof tilt of the steering apparatus 1 is controlled by driving a motor CM1(illustrated in FIG. 3) for tilt control of the steering apparatus 1. Inaddition, the steering apparatus 1 includes a telescopic mechanism C2.The amount of telescopic movement is controlled by driving a motor CM2for telescopic control of the steering apparatus 1.

Next, a detail of the energy absorption device 9 will be explained withreference to FIG. 2 to FIG. 7. FIG. 2 represents a side viewillustrating the steering apparatus 1 according to the embodiment of thepresent invention. FIG. 3 represents a plane view illustrating thesteering apparatus 1.

As illustrated in FIG. 3, in the embodiment, energy absorptionapparatuses 9 are provided at both sides of the column housing 2 a. Asillustrated in FIGS. 2 and 3, each energy absorption device 9 includesan energy absorption pin 11 (referred to an EA pin in later part) as asupport pin, an energy absorption member 12, a control pin 13 as aconnection member, a pin control device 14 as a control apparatus.

As illustrated in FIG. 3, a recessed portion B is provided at each rightand left side of the column housing 2 a along a line Ko orthogonal to alongitudinal direction of the steering shaft 3. The EA pin 11 ofcylindrical shape is press-fitted in each recessed portion B along theline Ko.

Further, a thin portion 7 a having a thickness becoming thinner in arearward direction, as illustrated in FIGS. 7 and 8, is provided at eachside of the column housing 2 a. The thin portion 7 a is provided at therear of the recessed portion B provided at each side (steering wheelside), as illustrated in FIGS. 2 and 3. As illustrated in FIG. 3, agroove Ho of U-character shape opening rearward is formed at each thinportion 7 a by means of notching.

The energy absorption member 12 is provided along each recessed portionB as illustrated in FIGS. 2 and 3. As illustrated in FIGS. 4A and 4B,the energy absorption member 12 is configured from two absorption plates12A and 12B layered together. A first absorption plate 12A is located ona second absorption plate 12B (In other words, the first absorptionplate 12A is located at the vehicle body 8 side of the second absorptionplate 12B). In addition, a thickness t1 of the first absorption plate12A is equal to a thickness t2 of the second absorption plate.

The first absorption plate 12A is configured from a base portion 15 a ofan approximately square shape and a belt-like portion 15 b extendedfrontward from the base portion 15 a. A first hole H1 a is provided atan approximately middle of the base portion 15 a. A second hole H1 b isprovided at the belt-like portion 15 b near the base portion 15 a. Thesecond hole H1 b is provided at a distance of Lo from the first hole H1a. In addition, a rivet 18 is provided at each right and left side ofthe belt-like portion 15 b of the first absorption plate 12A near thebase portion 15 a.

The second absorption plate 12B is configured from a base portion 17 aof an approximately square shape and a belt-like portion 17 b extendedfrom the base portion 17 a, as same as in the case of the firstabsorption plate 12A. In the embodiment, the belt-like portion 17 b ofthe second absorption plate 12B is configured to have a uniform width bnarrower than a width a of the belt-like portion 15 b of the firstabsorption plate 12A. In addition, the base portion 17 a of the secondabsorption plate 12B is formed to have a width equal to the width a ofthe belt-like portion 15 b of the first absorption plate 12A. Further, ahole H2 having an inner diameter equal to the second hole H1 b is formedapproximately at a center of the base portion 17 a of the secondabsorption plate 12B.

As illustrated in FIG. 5, the second absorption plate 12B is fastened tothe first absorption plate 12A by the rivets 18 so that the base portion17 a of the second absorption plate 12B is overlapped with the belt-likeportion 15 b of the first absorption plate 12A In this time, the secondhole H1 b formed at the belt-like portion 15 b of the first absorptionplate 12A overlaps with the hole H2 formed at the base portion 17 a ofthe second absorption plate 12B. Accordingly, the base portion 17 a ofthe second absorption plate 12B is shifted from the base portion 15 a ofthe first absorption plate 12A by a distance Lo in a frontwarddirection.

In addition, the base portion 17 a of the second absorption plate 12B isfixed by the rivets 18 with a sufficiently small load. Accordingly, whenexternal force (impact) equal to or larger than a predetermined level isapplied between the first absorption plate 12A and the second absorptionplate 12B, the first absorption plate 12A and the second absorptionplate 12B are separated.

Further, as illustrated in FIG. 4B, the belt-like portion 15 b of thefirst absorption plate 12A includes a bending portion 19 a. Similarly,the belt-like portion 17 b of the second absorption plate 12B includes abending portion 19 b. The bending portion 19 a of the first absorptionplate 12A is provided at the front of the second hole H1 b. The bendingportion 19 b of the second absorption plate 12B is provided at the frontof the hole H2.

Then, as illustrated in FIGS. 2 and 3, the absorption plate 12A and theabsorption plate 12B configured as described above and fastened togetherby the rivets 18 are disposed so that the bending portion 19 a and thebending portion 19 b are provided under the EA pin 11 secured in therecessed portion B and fitted to the EA pin 11. In this time, the baseportion 15 a of the first absorption plate 12A and the base portion 17 aof the second absorption plate 12B are disposed on the second supportmember 7.

The second support member 7 is attached to the thin portion 7 a of thecolumn housing 2 a. FIG. 7 represents a cross-sectional viewillustrating a schematic portion of the energy absorption apparatus 9taken on line VII-VII of FIG. 3. As illustrated in FIG. 7, the secondsupport member 7 has a cross-sectional shape configured fromapproximately two parallel sides and one side connected to both rightends of the two approximately parallel sides. As can be seen from FIG. 7and configuration described above, the second support member 7 has anopening at the front. The second support member 7 is fitted to the thinportion 7 a so that the thin portion 7 a is inserted into the secondsupport member 7 from the opening of the second support member 7.

In addition, a first upper wall 20 a and a second upper wall 20 b lowerthan the first upper wall 20 a by a difference of height To are providedat an upper wall 20 of the second support member 7. The second upperwall 20 b is provided at the front of the first upper wall portion 20 a.The difference of height To is set to be higher than a sum of thethickness t2 of the second absorption plate 12B and the thickness of therivets 18.

Further, a first penetrating hole Sa is provided at each first upperwall 20 a and a lower wall 21 facing the first upper wall 20 a Eachfirst penetrating hole Sa penetrates in an arrow Z direction (verticaldirection) in FIG. 7. Further, a second penetrating hole Sb is providedat each second upper wall 20 b and the lower wall 21 facing the secondupper wall 20 b. The second penetrating hole Sb penetrates in an arrow Zdirection (vertical direction) in FIG. 7. The first penetrating holes Saand the second penetrating holes Sb are formed along a longitudinaldirection of the steering shaft 3. The first penetrating holes Sa areprovided apart from the second penetrating holes Sb by the distance Lo.Accordingly, when the first absorption plate 12A and the secondabsorption plate 12B are disposed between the first upper wall 20 a andthe vehicle body 8 so that the base portion 15 a of the first absorptionplate 12A is sandwiched, the base portion 17 a of the second portion 12Bincluding the rivets 18 is disposed between the belt-like portion 15 bof the first absorption plate 12A and the second upper wall 20 b of thesecond support member 7.

Further, when the first penetrating holes Sa overlap with the first holeH1 a formed at the first absorption plate 12A, the second penetratingholes Sb overlap with the hole H2 formed at the second absorption plate12B and the second hole H1 b formed at the first absorption plate 12A.

The bolt G2 is inserted into the first penetrating holes Sa. The controlpin 13 serving as a connection member controlled by the pin controlapparatus 14 is inserted into the second penetrating holes Sb. Then, asillustrated in FIG. 3, when the second support member 7, into which thebolt G2 and the control pin 13 have been inserted, is fitted to the thinportion 7 a, the bolt G2 and the control pin 13 are disposed in thegroove Ho formed at the thin portion 7 a. Then, as illustrated in FIG.3, the bolt G2 is tightened to the vehicle body 8.

The pin control apparatus 14 is fixed to the lower wall 21 of aconnected body C of the second support member 7 and the thin portion 7 aof the column housing 2 a. The pin control apparatus 14 includes thecontrol pin 13 movable in an upper and lower direction. The control pin13 penetrates the second penetrating holes Sb and protruding from thesecond upper wall 20 b. Then, when the control pin 13 moves upward to aposition illustrated in FIG. 7, the control pin 13 engages with thesecond hole H1 b provided at the first absorption plate 12A and the holeH2 provided at the second absorption plate 12B at the same time.Further, when the control pin 13 moves downward from the positionillustrated in FIG. 7 to a position illustrated in FIG. 9, the controlpin 13 is disengaged from the second hole H1 b provided at the firstabsorption plate 12A and the hole H2 provided at the second absorptionplate 12B at the same time. Accordingly, when the control pin 13 islocated at the position illustrated in FIG. 7, both of the firstabsorption plate 12A and the second absorption plate 12B are connectedto the vehicle body 8 through the control pin 13, the connected body C,and the bolt G2. Then, when the control pin 13 is located at theposition illustrated in FIG. 9, only the first absorption plate 12A isconnected to the vehicle body 8 through the bolt G2. At this time, thesecond absorption plate 12B is not connected to the vehicle body 8.

FIG. 6 represents a cross-sectional view illustrating the control pin13. As illustrated in FIG. 6, a circular groove 25 is formed at an endportion of the control pin 13. The circular groove 25 is formed to havea width I equal to or larger than a sum of the thickness t1 of the firstabsorption plate 12A and the thickness t2 of the second absorption plate12B. Accordingly, when the control pin 13 is moved to the positionillustrated in FIG. 7, the circular groove 25 is engaged with the secondhole H1 b and the hole H2. Therefore, the control pin 13 is preventedfrom disengaging from the second hole H1 b provided at the firstabsorption plate 12A and the hole H2 provided at the second absorptionplate 12B caused by vibrations or the like.

As illustrated in FIG. 7, the pin control apparatus 14 is electricallyconnected with the controller 10 (illustrated in FIG. 1) through anelectric wire (not illustrated). An electromagnetic solenoid is providedinside the pin control apparatus 14. When the drive current SG issupplied from the controller 10, the solenoid is excited. Then, the pincontrol apparatus 14 moves the control pin 13 downward to the positionillustrated in FIG. 9. On the other hand, when the drive current SG isnot supplied from the controller 10, the solenoid is not excited. Then,the control pin 13 is moved upward to the position illustrated in FIG.7.

Accordingly, in the embodiment, when the weight of the driver H is lessthan 80 kg, the drive current SG is supplied from the controller 10, andthe control pin 13 is drawn downward. As a result, as the energyabsorption member 12, only the first absorption plate 12A is connectedand secured to the vehicle 8 through the bolt G2. On the other hand,when the weight of the driver H is 80 kg or more, the drive current SGis not supplied from the controller 10 and the control pin 13 is movedupward. As a result, as the energy absorption member 12, the firstabsorption plate 12A and the second absorption plate 12B are connectedto the vehicle body 8 through the control pin 13, the connected body C,and the bolt G2.

Next, an action of the steering apparatus 1 configured as describedabove will be explained with reference to FIGS. 7 to 10.

FIG. 7 represents a diagram illustrating a relation between the EA pin11 and the energy absorption member 12 before the driver H takes thedriver seat S. In this condition, the drive current SG is not suppliedfrom the controller 10 and the solenoid of the pin control apparatus 14is not excited. Accordingly, the control pin 13 is protruding upward andengaging with the second hole H1 b of the first absorption plate 12A andthe hole H2 of the second absorption plate 12B. As a result, both of thefirst absorption plate 12A and the second absorption plate 12B areconnected with the vehicle body 8.

Then, when the controller 10 judges that the weight of the driver H is80 kg or more, the controller 10 does not supply the drive current SG.Accordingly, the solenoid of the pin control apparatus 14 is notexcited, and as illustrated in FIG. 7, the control pin 13 keepsprotruding upward. As a result, both of the first absorption plate 12Aand the second absorption plate 12B are connected with the vehicle body8.

Then, in this condition, when the vehicle collides with an object andthe steering column apparatus 2 is detached from the vehicle body 8 andmoved in a forward direction, as illustrated in FIG. 8, the EA pin 11 ismoved relative to the first absorption plate 12A and the secondabsorption plate 12B while the EA pin 11 makes changes of shapes of thefirst absorption plate 12A and the second absorption plate 12B. In otherwords, the EA pin 11 is removed from both of the first absorption plate12A and the second absorption plate 12B. As a result, load applied tothe EA pin 11 when the EA pin 11 is removed becomes relatively large.

Accordingly, when the weight of the driver H is 80 kg or more, loadapplied to the steering column apparatus 2 when the steering columnapparatus 2 is detached from the vehicle body 8 and moved becomesrelatively large. As described above, when the weight of the driver H isrelatively large, the steering apparatus 1 can sufficiently absorbimpact applied to the driver H.

On the other hand, when the controller 10 judges that the weight of thedriver H is less than 80 kg, the controller 10 outputs the drive currentSG. Then, the solenoid of the pin control apparatus 14 is excited, andas illustrated in FIG. 9, the control pin 13 is moved downward. As aresult, only the first absorption plate 12A is connected to the vehiclebody 8.

In this condition, when the vehicle collides with an object and thesteering column apparatus 2 is detached from the vehicle body 8 andmoved in a forward direction, as illustrated in FIG. 10, the secondabsorption plate 12B is detached from the rivets 18 and is moved in aforward direction together with the steering column apparatus 2. Then,the EA pin 11 is moved relative to only the first absorption plate 12Awhile the EA pin 11 makes a change of a shape of only the firstabsorption plate 12A. As a result, load applied to the EA pin 11 whenthe EA pin is removed becomes relatively small.

In other words, load applied to the EA pin 11 when the EA pin 11 isremoved depends on a thickness and a width of the energy absorptionplate. When the thickness and the width of the energy absorption platebecome large, the load applied to the EA pin 11 when the EA pin 11 isremoved becomes large. In the embodiment, the thickness of the firstabsorption plate 12A and that of the second absorption plate 12B are thesame. The width of the second absorption plate 12B is narrower than thatof the first absorption plate 12A.

Accordingly, when the weight of the driver is less than 80 kg, the loadapplied to the steering column 2 when the steering column apparatus 2detached from the vehicle body 8 and moved becomes relatively small.Even when the weight of the driver H is small, the steering apparatus 1can gently absorb the impact applied to the driver H.

In this configuration, for example, if the drive current SG is disruptedfrom some reasons when the vehicle collides with an object, the controlpin 13 will be moved upward. In this time, because the first absorptionplate 12A and the second absorption plate 12B has been alreadyseparated, the control pin 13 can engage with only the second hole H1 bof the first absorption plate 12A. Accordingly, large load is notapplied to the EA pin 11 when the EA pin 11 is removed. Thus, the energyabsorption apparatus 9 can work safely.

Next, effects of the embodiment of the present invention will beexplained.

According to the embodiment of the present invention, the energyabsorption member 12 is configured from the first absorption plate 12Aand the second absorption plate 12B overlapping with the firstabsorption plate 12A. Then, when the weight of the driver H is astandard weight or more, the control pin 13 is controlled so that thecontrol pin 13 is removed from both the first absorption plate 12A andthe second absorption plate 12B, thereby increasing the load applied tothe EA pin 11 when the EA pin is removed. On the other hand, when theweight of the driver H is less than the standard weight, the control pin13 is controlled so that the control pin 13 is removed from only thefirst absorption plate 12A, thereby decreasing the load applied to theEA pin 11 when the EA pin 11 is removed.

Accordingly, the load applied to the EA pin 11 when the EA pin 11 isremoved can be controlled by only driving and controlling the controlpin 13 corresponding to the weight of the driver H. Therefore, theenergy absorption apparatus 9 can be simply configured.

According to the embodiment, in the pin control apparatus 14, thecontrol pin 13 is driven and controlled by means of the solenoid.Accordingly, electronic configurations of the pin control apparatus 14can be simple. Therefore, the pin control apparatus 14 can be smallersize. Further, the pin control apparatus 14 can be manufactured at lowercost. As a result, the steering apparatus also can be manufactured atlower cost.

According to the embodiment of the present invention, in the steeringapparatus 1 including the tilt mechanism C1 and the telescopic mechanismC2, the energy absorption apparatus 9 can be smaller size.

According to the embodiment of the present invention, because the EA pin11, the first absorption plate 12A, and the second absorption plate 12Bare provided at each side of the column housing 2 a, when the vehiclecollides with an object, balance between load applied to the EA pin 11provided at right side and load applied to the EA pin 11 provided atleft side when the EA pins 11 are removed can be preferably maintained.Alternately, an EA pin 11 and a first absorption plate 12A and a secondabsorption plate 12B can be provided at a center of the column housing 2a.

Next, a second embodiment of the present invention will be explainedwith reference to FIG. 11. In the second embodiment, same configurationmembers will be numbered as same as in the first embodiment, anddetailed descriptions of the same configuration members will be skipped.FIG. 11 represents a diagram illustrating a relation between the controlpin 13 and the energy absorption member 12 according to the secondembodiment of the present invention.

As illustrated in FIG. 11, the pin control apparatus 14 is assembled tothe vehicle body 8 according to the second embodiment of the presentinvention. Then, the control pin 13 is inserted from the vehicle body 8side toward the second upper wall 20 b of the connected body C andconfigured to contact with the second upper wall 20 b according to thesecond embodiment of the present invention. Further, in the pin controlapparatus 14 according to the second embodiment of the presentinvention, when the solenoid is excited, the control pin 13 is movedupward (an arrow Z direction in FIG. 11). On the other hand, when thesolenoid is not excited, the control pin 13 is moved downward (aninversed direction of the arrow Z direction in FIG. 11).

Next, a third embodiment of the present invention will be explained withreference to FIG. 12. In the third embodiment, same configurationmembers are numbered as same as in the first embodiment, and detaileddescriptions of the same configuration members will be skipped. FIG. 12represents a diagram illustrating a relation between the control pin 13and the energy absorption member 12 according to the third embodiment ofthe present invention.

As illustrated in FIG. 12, in the third embodiment, the energyabsorption member 12 is configured from three absorption plates, thatis, the first absorption plate 12A, the second absorption plate 12B, anda third absorption plate 12C. Then, the first absorption plate 12Aincludes the first hole H1 a, the second hole H1 b and a third hole H1 cformed at the front of the hole H2 b. Further, the second absorptionplate 12B includes the hole H2 and a hole H2 a formed at the front ofthe hole H2. Further, the third absorption plate 12C includes a baseportion and a hole H3 formed at the base portion. Then, when the firstabsorption plate 12A, the second absorption plate 12B, and the thirdabsorption plate 12C are overlapped together, as illustrated in FIG. 12,the hole H3 of the third absorption plate 12C is disposed so as to facethe hole H2 a of the second absorption plate 12B.

In addition, a second pin control apparatus 27 is secured on the lowerwall 21 of the second support member 7. The second pin control apparatus27 controls and moves a control pin 26 in upper and lower direction. Thecontrol pin 26 is inserted into the hole H2 a of the second absorptionplate 12B and the hole H3 of the third absorption plate 12C. The secondpin control apparatus 27 is connected to the controller 10 for inputtinga drive current SG corresponding to the weight of the driver H.

Configured as described above, for example, by protruding the twocontrol pins 13 and 26 simultaneously, the EA pin 11 can be removed fromthree absorption plates 12A, 12B, and 12C while the EA pin 11 changesshapes of the three absorption plates 12A, 12B, and 12C. As a result, itcan be effective when load applied to the EA pin 11 when the EA pin 11is removed need to be larger. In other words, by controlling the twocontrol pins 13 and 26, the number of the absorption plates from whichthe EA pin 11 is removed can be varied, thereby varying the load appliedto the EA pin 11 when the EA pin 11 is removed in wider variety.

In addition, embodiments of the present invention are not limited toabove described embodiments. Variations can be employed as follows.

In the embodiment described above, the EA pin 11 and the energyabsorption member 12 were provided at each side of the column housing 2(right and left side). The energy absorption member 12 was configuredfrom layers of two absorption plates, that is, the first absorptionplate 12A and the second absorption plate 12B. Alternately, the energyabsorption member 12 can be configured from one absorption plate. Inthis case, the EA pin 11 is removed from only either one of theabsorption plates corresponding to the weight of the driver H. Thesteering apparatus configured like that can control the load applied tothe EA pin 11 when the EA pin 11 is removed corresponding to the weightof the driver H.

In the embodiments described above, the control pin 13 was moved upwardor downward to control the number of the absorption plates from whichthe EA pin 11 is removed corresponding to the weight of the driver H asa drive condition. However, it is not limited. The number of theabsorption plates from which the EA pin 11 is removed can be controlledcorresponding to whether a seat belt is applied to the driver H or not.Further, the number of the absorption plates from which the EA pin 11 isremoved can be controlled by a camera provided in the vehicle forjudging a figure of the driver corresponding to a result of judging thefigure. Further, the number of the absorption plates from which the EApin 11 is removed can be controlled corresponding to a speed of thevehicle.

In the embodiment described above, the steering apparatus 1 included thetilt mechanism C1 and the telescopic mechanism C2. However, it is notlimited. The present invention can also be applied to a steeringapparatus including neither a tilt mechanism C1 nor a telescopicmechanism C2. The present invention can also be applied to a steeringapparatus including either a tilt mechanism C1 or a telescopic mechanismC2.

In the embodiment described above, the belt-like portion 17 b of thesecond absorption plate 12B had a uniform width. However, it is notlimited. As illustrated in FIG. 13, the width of the belt-like portion17 b of the second absorption plate 12B can be gradually changed.Configured like that, load applied to the steering column apparatus 2can be changed corresponding to a moved distance of the steering columnapparatus 2 when the vehicle collides with an object.

Further, as illustrated in FIG. 14, by providing a hole Ro at thebelt-like portion 15 b of the first absorption plate 12A, load appliedto the EA pin 11 when the EA pin 11 is removed from the first absorptionplate 12A can be changed corresponding to a moved distance when thevehicle collides with an object.

Next, another technical concept which can be grasped on the basis of theembodiments of the present invention described above will be mentioned.

An energy absorbing steering apparatus for a vehicle, comprising asupport member for supporting a steering column by detachably attachingthe steering column to a vehicle body and an energy absorption apparatusfor relatively movably supporting the steering column relative to thevehicle body in a frontward direction of the vehicle body, and forabsorbing impact energy applied to the steering column, the energyabsorption apparatus comprising a support pin provided each right andleft side of the steering column and supported by the steering column,an absorption member provided along the support pin provided each rightand left side of the steering column and having a connection portionprovided at one end of the absorption member and connected to thevehicle body for applying load to the support pin when the support pinmoves relative to the support member, a connection member connected tothe connection portion of the absorption member provided along thesupport pin for connecting the absorption member to the vehicle body,and a control apparatus for controlling the connection member to connecteither one of the connection portion of the absorption member to thevehicle body corresponding to a drive condition.

According to another technical concept described above, the amount ofabsorbed impact energy applied to the steering column can be controlledby selecting whether to connect either one of each absorption memberprovided each right and left side of the support member with the vehicleor to connect both of each absorption member with the vehiclecorresponding to the drive condition.

According to a first aspect of the present invention, an energyabsorbing steering apparatus for a vehicle includes a support member forsupporting a steering column by detachably attaching the steering columnto a vehicle body and an energy absorption apparatus for relativelymovably supporting the steering column relative to the vehicle body in afrontward direction of the vehicle body. The energy absorbing apparatusis designed for absorbing impact energy applied to the steering column.The energy absorption apparatus includes a support pin supported by thesteering column, a first absorption member provided along the supportpin and having a connection portion provided at one end of the firstabsorption member and connected to the vehicle body for applying load tothe support pin when the support pin moves relative to the supportmember, a second absorption member provided along the support pin andhaving a connection portion provided at one end of the second absorptionmember and connected to the vehicle body for applying load to thesupport pin when the support pin moves relative to the support member, aconnection member connected to the connection portion of the firstabsorption member and the connection portion of the second absorptionmember for connecting the first absorption member and the secondabsorption member to the vehicle body, and a control apparatus forcontrolling the connection member to change the number of absorptionmembers connected to the vehicle body corresponding to a drivecondition.

According to a second aspect of the present invention, in the energyabsorbing steering apparatus for a vehicle according to the first aspectof the present invention, the support pin is provided at each right sideand left side of the support member, and the first absorption member andthe second absorption member are provided along the support pin providedat each right side and left side of the support member.

According to a third aspect of the present invention, in the energyabsorbing steering apparatus for a vehicle according to the first aspectof the present invention, the first absorption member includes a firstplate of belt-like shape, the second absorption member includes a secondplate of belt-like shape, the connection member is two holes, oneprovided at the first plate and the other provided at the second plate,the first plate and the second plate are overlapped so that the holeprovided at the first plate and the hole provided at the second plateare overlapped together, and the connection member includes a controlpin for connecting the first plate and the second plate to the vehiclebody by being inserted into and engaging with the hole provided at thefirst plate and the hole provided at the second plate.

According to a fourth aspect of the present invention, in the energyabsorbing steering apparatus for a vehicle according to the third aspectof the present invention, the first plate is connected to the vehiclebody through a connection bolt, and the second plate is fastened to thefirst plate by a rivet provided at the first plate.

According to a fifth aspect of the present invention, the energyabsorbing steering apparatus for a vehicle according to the first aspectof the present invention further includes a detection means provided atthe vehicle body for detecting the drive condition. The controlapparatus controls a position of the connection member corresponding tothe drive condition detected by the detection means.

According to a sixth aspect of the present invention, in the energyabsorbing steering apparatus for a vehicle according to the fifth aspectof the present invention, the detection means detects a weight of adriver driving the vehicle.

According to the first aspect of the present invention, the controlapparatus changes the number of absorption members connected with thevehicle body corresponding to the drive condition. Accordingly, forexample, when a weight of a driver is employed as the drive condition,the control member connects increased number of absorption members withthe vehicle body when the weight of the driver is heavy. On the otherhand, the control member connects one or decreased number of absorptionmembers with the vehicle body when the weight of the driver is light.Therefore, when increased number of absorption member is connected, loadapplied to the support pin when the support pin is removed becomeslarger. Accordingly, when the weight of the driver is heavy, the energyabsorbing steering apparatus can sufficiently absorb the impact energy.On the other hand, when the weight of the driver is light, the energyabsorbing steering apparatus can gently absorb the impact energy.Accordingly, an energy absorbing steering apparatus, in which the amountof impact energy absorbed can be controlled corresponding to the drivecondition, of relatively simple configuration can be provided.

According to the second aspect of the present invention, because thesupport pin and absorption members are provided at each side of thesupport member, load applied to each right and left side of the supportmember when the support pin is removed can be preferably maintained.

According to the third aspect of the present invention, the control pinis inserted into the holes provided at the first plate and the secondplate. Thus, the first plate and the second plate are connected with thevehicle body. Accordingly, the load applied to the support pin when thesupport pin is removed can be controlled.

According to the fourth aspect of the present invention, the firstabsorption member and the second absorption member can be supported as aunit.

According to the fifth aspect of the present invention, the controlapparatus connects a predetermined number of absorption members to thevehicle body corresponding to the drive condition detected by thedetection means. Accordingly, when the detection means is configured todetect the weight of the driver, the control apparatus can connect thepredetermined number of absorption members to the vehicle bodycorresponding to the weight of the driver.

According to the sixth aspect of the present invention, thepredetermined number of absorption members are connected to the vehiclecorresponding to the weight of the driver. Accordingly, the amount ofimpact energy absorbed by the absorption plate can be controlledcorresponding to the weight of the driver.

The principles, preferred embodiment and mode of operation of thepresent invention have been described in the foregoing specification.However, the invention which is intended to be protected is not to beconstrued as limited to the particular embodiments disclosed. Further,the embodiments described herein are to be regarded as illustrativerather than restrictive. Variations and changes may be made by others,and equivalents employed, without departing from the spirit of thepresent invention. Accordingly, it is expressly intended that all suchvariations, changes and equivalents which fall within the spirit andscope of the present invention as defined in the claims, be embracedthereby.

1. An energy absorbing steering apparatus for a vehicle, comprising: asupport member for supporting a steering column by detachably attachingthe steering column to a vehicle body; and an energy absorptionapparatus for relatively movably supporting the steering column relativeto the vehicle body in a frontward direction of the vehicle body, andfor absorbing impact energy applied to the steering column, the energyabsorption apparatus comprising: a support pin supported by the steeringcolumn; a first absorption plate provided along the support pin andhaving a connection portion provided at one end of the first absorptionplate, and the first absorption plate connected to the vehicle body forapplying load to the support pin when the support pin moves relative tothe support member; a second absorption plate provided along the supportpin to overlap with the first absorption plate in the thicknessdirection, the second absorption plate having a connection portionprovided at one end of the second absorption plate, and the secondabsorption plate connected to the vehicle body for applying load to thesupport pin when the support pin moves relative to the support member; aconnection member connected to both the connection portion of the firstabsorption plate and the connection portion of the second absorptionplate for connecting both the first absorption plate and the secondabsorption plate to the vehicle body; and a control apparatus forcontrolling the connection member to change the number of the absorptionplates connected to the vehicle body in response to a drive condition.2. The energy absorbing steering apparatus for a vehicle according toclaim 1, wherein the support pin is provided at each right side and leftside of the support member, and the first absorption plate and thesecond absorption plate are provided along the support pin provided ateach right side and left side of the support member.
 3. The energyabsorbing steering apparatus for a vehicle according to claim 1, whereinthe first and second absorption plates have a belt-like shape,respectively, the connection portion provided at the first absorptionplate is a first hole, the connection portion provided at the secondabsorption plate is a second hole, the first and second holes overlapeach other, and the connection member includes a control pin forconnecting the first and second absorption plates to the vehicle body bybeing inserted into and engaging with the first and the second holes. 4.The energy absorbing steering apparatus for a vehicle according to claim3, wherein the first absorption plate is connected to the vehicle bodythrough a connection bolt, and the second absorption plate is fastenedto the first absorption plate by a rivet provided at the firstabsorption plate.
 5. The energy absorbing steering apparatus for avehicle according to claim 3, further comprising: a detection meansprovided at the vehicle body for detecting the drive condition, whereinthe control apparatus controls a position of the connection member inresponse to the drive condition detected by the detection means.
 6. Theenergy absorbing steering apparatus for a vehicle according to claim 3,further comprising: a detection means for detecting a weight of a driverdriving the vehicle, wherein the first absorption plate is connected tothe vehicle body through a connection bolt, the control apparatuscontrols the control pin to connect both the connection portion providedat the first absorption plate and the connection portion provided at thesecond absorption plate to the vehicle body when the weight of thedriver detected by the detection means is a standard weight or more, andthe control apparatus controls the control pin to disconnect theconnection portion provided at the second absorption plate from thevehicle body when the weight of the driver detected by the detectionmeans is less than the standard weight.
 7. The energy absorbing steeringapparatus for a vehicle according to claim 6, wherein the firstabsorption plate includes a rivet for fastening the second absorptionplate, the fastening by the rivet is unfastened when a predeterminedlevel of impact or more is applied to the steering column, and thesecond absorption plate is detached from the first absorption plate bythe impact applied to the steering column when the weight of the driveris less than the standard weight.
 8. The energy absorbing steeringapparatus for a vehicle according to claim 1, further comprising: adetection means provided at the vehicle body for detecting the drivecondition, wherein the control apparatus controls a position of theconnection member in response to the drive condition detected by thedetection means.
 9. The energy absorbing steering apparatus for avehicle according to claim 8, wherein the detection means detects aweight of a driver driving the vehicle.
 10. The energy absorbingsteering apparatus for a vehicle according to claim 8, wherein thecontrol apparatus controls the connection member so that the number ofthe absorption members connected to the vehicle body when a weight of adriver detected by the detection means is less than a standard weightbecomes smaller than the number of absorption members connected to thevehicle body when the weight of the driver detected by the detectionmeans is the standard weight or more.
 11. The energy absorbing steeringapparatus for a vehicle according to claim 1, wherein the connectionportion provided at the first absorption plate is a first through hole,the connection portion provided at the second absorption plate is asecond through hole, the first and second through holes overlap eachother.
 12. The energy absorbing steering apparatus for a vehicleaccording to claim 11, wherein the control apparatus controls theconnection member to move in the thickness direction of the first andsecond absorption plates through the first and second through holes. 13.An energy absorbing steering apparatus for a vehicle, comprising: asupport member for supporting a steering column by detachably attachingthe steering column to a vehicle body; and an energy absorptionapparatus for relatively movably supporting the steering column relativeto the vehicle body in a frontward direction of the vehicle body, andfor absorbing impact energy applied to the steering column, the energyabsorption apparatus comprising: a support pin supported by the steeringcolumn, a first absorption plate engaged with the support pin and havinga connection portion provided at one end of the first absorption plate,and the first absorption plate connected to the vehicle body forapplying load to the support pin when the support pin moves relative tothe support member, a second absorption plate engaged with the supportpin to overlap with the first absorption plate in the thicknessdirection, the second absorption plate having a connection portionprovided at one end of the second absorption plate, and the secondabsorption plate connected to the vehicle body for applying load to thesupport pin when the support pin moves relative to the support member, aconnection member connected to both the connection portion of the firstabsorption plate and the connection portion of the second absorptionplate for connecting both the first absorption plate and the secondabsorption plate to the vehicle body, and a control apparatus forcontrolling the connection member to change the number of the absorptionplates connected to the vehicle body in response to a drive condition.